// See LICENSE.SiFive for license details.
package org.chipsalliance

import chisel3.experimental.{SourceInfo, SourceLine}
import org.chipsalliance.cde.config.Parameters
import org.chipsalliance.diplomacy.lazymodule.ModuleValue
import org.chipsalliance.diplomacy.nodes.{MonitorsEnabled, RenderFlipped}

// TODO - remove after full deprecation of old ValName Macro api

import scala.language.implicitConversions

/** Diplomacy is a set of abstractions for describing directed, acyclic graphs where parameters will be negotiated
  * between nodes. These abstractions are expressed in the form of abstract classes, traits, and type parameters, which
  * comprises nearly all of the types defined in this package.
  *
  * The [[NodeImp]] ("node implementation") is the main abstract type that associates the type parameters of all other
  * abstract types. Defining a concrete implementation of [[NodeImp]] will therefore determine concrete types for all
  * type parameters. For example, passing in a concrete instance of NodeImp to a SourceNode will fully determine
  * concrete types for all of a SourceNode's type parameters.
  *
  * Specific applications of Diplomacy are expected to either extend these types or to specify concrete types for the
  * type parameters. This allows for creating and associating application-specific node, edge, parameter, and bundle
  * types.
  *
  * =Concepts, metaphors, and mnemonics to help with understanding Diplomacy code=
  *
  * ==Parameter Types==
  *
  * There are several types of parameters involved in diplomacy code.
  *
  *   - Upward-flowing/Downward-flowing Parameters: These parameter types flow along edges and can be considered as the
  *     pre-negotiated, unresolved parameters.
  *   - Edge Parameters: These parameters are the result of the diplomatic negotiation and that is resolved for each
  *     edge. They are metadata, or an abstract concept of the connection represented by their edge, and contain any
  *     sort. These are an abstract concept which carry any sort of conceptual information that is useful to pass along
  *     the graph edge. For example, the full address map visible from a given edge and the supported access types for
  *     each memory region.
  *   - "p" Parameters: These are parameters of type [[Parameters]] which are implicit and generally available in
  *     various stages of the diplomacy codebase. Often they are captured from the context in which a particular
  *     diplomatic node or edge is created or bound.
  *   - Bundle Parameters: These parameters are used for actual hardware generation of the [[chisel3.Data]]s which
  *     connect diplomatic components. In contrast to edge parameters, this may carry information like the width of an
  *     address or opcode field. While they are derived from Edge parameters holding all metadata computed over an edge,
  *     Bundle parameters often contain only concrete information required to create the hardware type, such as
  *     [[freechips.rocketchip.tilelink.TLBundleParameters]] and [[freechips.rocketchip.amba.axi4.AXI4BundleParameters]]
  *
  * ==Inward/Outward vs. Upward/Downward==
  *
  * Diplomacy defines two dimensions: inward/outward and upward/downward.
  *
  * Inward/outward refer to the direction of edges from the perspective of a given node. For a given node:
  *   - Inward refers to edges that point into itself.
  *   - Outward refers to edges that point out from itself.
  *
  * Therefore, a given edge is always described as inward to one node and as outward from another.
  *
  * Upward/downward refer to the direction of the overall directed acyclic graph. Because each each edge is directed, we
  * say that the directions flow from sources (nodes that only have outward edges) downwards to sinks (nodes that only
  * have inward edges), or from sinks upwards to sources. These terms are used in parameter negotiation, where
  * parameters flow both upwards and downwards on edges. Note that diplomacy avoids terms like "master/slave",
  * "producer/consumer", though these can be defined by the concrete implementations of diplomatic systems. Such terms
  * imply something about the transactional behavior of agents within a protocol, whereas source/sink and up/down refer
  * only to the structure of the graph and the flow of parameters.
  *   - Upward refers to the flow of parameters along edges in the upwards direction.
  *   - Downward refers to a flow of parameters along edges in the downwards direction.
  *
  * A useful mnemonic for distinguishing between upward and downward is to imagine a diplomatic graph as a literal
  * network of rivers where water flows in the direction of the edges, and parameters that move in the upstream
  * direction, while downward refers to parameters that move in the downstream direction.
  *
  * ==Acronyms==
  *
  * Diplomacy has some commonly used acronyms described below: D[IO], U[IO], E[IO], B[IO] are the types of parameters
  * which will be propagated. D: Downwards -- parameters passed in the same direction as the edge. U: Upwards --
  * parameters passed in the opposite direction as the edge. E: Edge -- resolved (negotiated) parameters describing
  * conceptual information on graph edges. B: Bundle should extends from [[chisel3.Data]].
  *
  * {{{
  *
  *         Upwards (a.k.a. towards Sources)          ↓
  *                                                   ↓
  *         inward edge of (parameter) type EI        ↓
  *         created from parameters of type UI and DI ↓
  *         will result in a Bundle of type BI        ↓
  *                                                   ↓
  *                                                ^  ↓  *
  *                                                .  ↓  *
  *                ┌───────────────────────────────.──↓──*───────────────────────────────┐
  *                │                               .  ↓  *                    BaseNode   │
  *                │                               .  ↓  *                    (NodeImp)  │
  *                │                               .  ↓  *                               │
  *                │  ┌────────────────────────────.──↓──*────────────────────────────┐  │
  *                │  │                            .  ↓  *  InwardNode (InwardNodeImp)│  │
  *                │  │                         (mixI)↓  *                            │  │
  *                │  │                            .  ↓  *                            │  │
  *                │  │  Upward-flowing inwards    .  ↓  * Downward-Flowing inwards   │  │
  *                │  │  parameters of type UI     .  ↓  * parameters of type DI      │  │
  *                │  └────────────────────────────.──↓──*────────────────────────────┘  │
  *                │                               .  ↓  *                               │
  *                │                               .  I  v                               │
  *                │                     (mapParamsU)    (mapParamsD)                    │
  *                │                               ^  O  +                               │
  *                │                               :  ↓  +                               │
  *                │  ┌────────────────────────────:──↓──+────────────────────────────┐  │
  *                │  │                            :  ↓  + OutwardNode(OutwardNodeImp)│  │
  *                │  │                            :  ↓ (mixO)                        │  │
  *                │  │                            :  ↓  +                            │  │
  *                │  │  Upward-flowing outwards   :  ↓  + Downward-Flowing outward   │  │
  *                │  │    parameters of type UO   :  ↓  + parameters of type DO      │  │
  *                │  └────────────────────────────:──↓──+────────────────────────────┘  │
  *                │                               :  ↓  +                               │
  *                │                               :  ↓  +                               │
  *                └───────────────────────────────.──↓──*───────────────────────────────┘
  *                                                :  ↓  *
  *                                                :  ↓  v
  *                                                   ↓ outward edge of (parameter) type EO
  *                                                   ↓ created from parameters of type UO and DO
  *                                                   ↓ will result in a Bundle of type BO
  *                                                   ↓
  *                                                   ↓ Downwards (a.k.a. towards Sinks)
  *
  * }}}
  *
  * ==Handles==
  *
  * Two Diplomatic nodes can be bound together using the `:=` operator or one of its sibling operators. Binding is
  * asymmetric, and the binding operation will connect the outward of one node to the inward of the other.
  *
  * For example, the expression `a := b` will connect the outward of `b` to the inward of `a`.
  *
  * We would like the `:=` operator to have additional properties that make it intuitive to use:
  *
  *   1. It should be chainable, so that `a := b := c` will have the intuitive effect of binding c to b and b to a. This
  *      requires that the return type of `:=` be the same as its arguments, because the result of one `:=` operation
  *      must be valid as an argument to other `:=` operations.
  *
  * 2. It should be associative, so that `(a := b) := c` is equivalent to `a := (b := c).` This means that the order in
  * which the bind operations execute does not matter, even if split across multiple files.
  *
  * 3. `a := b` should only be allowed if and only if `b` allows outward edges and `a` allows inward edges. This should
  * be preserved even when chaining operations, and it should ideally be enforced at compile time.
  *
  * [[NodeHandle]] are a way of satisfying all of these properties. A Handle represents the aggregation of a chain of
  * Nodes, and it preserves information about the connectability of the innermost and the outermost sides of the chain.
  *
  * If `b` supports inward edges, then `a := b` returns a [[NodeHandle]] that supports inward edges that go into `b`. If
  * `a` supports outward edges, then `a := b` returns a [[NodeHandle]] that supports outward edges coming out of `a`.
  *
  * ==Node Terms==
  *
  * These are some conventionally used terms for diplomatic Nodes, which describe different common subtypes that certain
  * protocol implementation might utilize:
  *   - Mixed: implies that the inward and outward NodeImp are not the same (some sort of protocol conversion is
  *     occurring between the two implementations).
  *   - Adapter: the number of inward and outward edges must be the same.
  *   - Nexus: the number of nodes connecting from either side are unknown until the graph is constructed and can differ
  *     from one another.
  *   - Identity: modifies neither the parameters nor the protocol-specific circuitry for the edges that pass through
  *     it.
  *   - Source: cannot have inward edges.
  *   - Sink: cannot have outward edges.
  *   - Junction: the number of inward and outward edges must have a fixed ratio to one another
  *   - Ephemeral: a temporary placeholder used for connectivity operations
  */
package object diplomacy {

  type ValName = sourcecode.Name

  // TODO - replace with type alias when name accessor is fully deprecated.
  implicit class SourcecodeNameExt(private val x: sourcecode.Name) {
    @deprecated("Name method has been removed in transition to sourcecode library.", "diplomacy 1.0.0")
    def name:  String = x.value
    def value: String = x.value
  }

  def ValName(value: String): ValName = sourcecode.Name(value)

  private[diplomacy] def sourceLine(sourceInfo: SourceInfo, prefix: String = " (", suffix: String = ")") =
    sourceInfo match {
      case SourceLine(filename, line, col) => s"$prefix$filename:$line:$col$suffix"
      case _                               => ""
    }

  def EnableMonitors[T](
    body:       Parameters => T
  )(
    implicit p: Parameters
  ) = body(p.alterPartial { case MonitorsEnabled => true })

  def DisableMonitors[T](
    body:       Parameters => T
  )(
    implicit p: Parameters
  ) = body(p.alterPartial { case MonitorsEnabled => false })

  def FlipRendering[T](
    body:       Parameters => T
  )(
    implicit p: Parameters
  ) = body(p.alterPartial { case RenderFlipped => !p(RenderFlipped) })

  implicit def moduleValue[T](value: ModuleValue[T]): T = value.getWrappedValue
}
